Evaluations of some series via the WZ method

Qing-Hu Hou; Zhi-Wei Sun

arxiv: 2604.15172 · v1 · submitted 2026-04-16 · 🧮 math.CO · math.NT

Evaluations of some series via the WZ method

Qing-Hu Hou , Zhi-Wei Sun This is my paper

Pith reviewed 2026-05-10 10:43 UTC · model grok-4.3

classification 🧮 math.CO math.NT

keywords WZ methodhypergeometric seriesbinomial coefficientszeta functionsseries evaluationconjecturesgamma functions

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The pith

WZ method proves two series sum to 3/π and 1959/2 ζ(6) minus 432 ζ(3)^2

A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.

The paper applies the Wilf-Zeilberger method to establish two infinite-series identities that one author had previously conjectured. One identity shows that a sum over k involving the fifth power of the central binomial coefficient, together with linear and other binomial factors, equals exactly three divided by pi. The second shows that summing the fourth derivative with respect to k of a ratio of gamma functions equals a concrete linear combination of zeta at six and the square of zeta at three. The proofs proceed by constructing explicit certificates that turn each sum into a telescoping series whose boundary terms produce the claimed constants. These results confirm the conjectures and supply rigorous closed forms for the given hypergeometric expressions.

Core claim

The authors prove that the sum from k=0 to infinity of (28k² + 10k + 1) times binomial(2k,k)^5 divided by (6k+1) times (-64)^k times binomial(3k,k) times binomial(6k,3k) equals 3/π, and that the sum from k=1 to infinity of the fourth derivative with respect to k of (21k-8) Γ(k+1)^2 over (k^3 Γ(2k+1)) equals 1959/2 ζ(6) minus 432 ζ(3)^2. Both proofs rely on the construction of WZ certificates for the respective summands that yield exact telescoping relations after summation.

What carries the argument

WZ certificates, which are auxiliary terms that satisfy a telescoping difference relation for the hypergeometric summand in the summation index.

If this is right

The first series converges exactly to 3/π.
The second sum equals exactly 1959/2 ζ(6) - 432 ζ(3)^2.
The two conjectures are thereby confirmed as theorems.
The same certificate construction works for the additional series evaluated in the paper.

Where Pith is reading between the lines

These are editorial extensions of the paper, not claims the author makes directly.

The technique may succeed for other series conjectured by the same author that involve comparable powers of binomial coefficients.
Similar WZ applications could produce further closed forms linking binomial sums to pi and to products of zeta values.
The existence of the certificates suggests that many such identities admit purely algebraic proofs without separate convergence analysis.

Load-bearing premise

That explicit WZ certificates exist for these hypergeometric terms and that the resulting telescoping sums converge directly to the stated closed forms.

What would settle it

Numerical computation of partial sums of the first series up to a large finite upper limit that deviates from 3/π by more than the expected truncation error, or the second sum failing to match the numerical value of the right-hand side.

read the original abstract

In this paper, we evaluate some series via the WZ method, and confirm several previous conjectures. For example, we prove the following two identities conjectured by the second author: $$\sum_{k=0}^{\infty} \frac{(28k^2 + 10k + 1) \binom{2k}{k}^5}{(6k + 1)(-64)^k \binom{3k}{k} \binom{6k}{3k}} = \frac{3}{\pi}$$ and $$\sum_{k=1}^\infty \frac{d^4}{dk^4}\left(\frac{(21k-8)\Gamma(k+1)^2}{k^3\Gamma(2k+1)}\right)=\frac{1959}2\zeta(6)-432\zeta(3)^2. $$

Editorial analysis

A structured set of objections, weighed in public.

Desk editor's note, referee report, simulated authors' rebuttal, and a circularity audit. Tearing a paper down is the easy half of reading it; the pith above is the substance, this is the friction.

Desk Editor's Note private letter to a colleague

Hou and Sun prove two of Sun's conjectures with the WZ method, but the second identity's fourth derivative step needs explicit justification since it leaves the hypergeometric setting.

read the letter

Hou and Sun have written proofs for two series that the second author had conjectured earlier. One sums a certain rational multiple of fifth powers of central binomials to 3/pi. The other sums the fourth derivative with respect to k of (21k-8) times Gamma(k+1)^2 over k^3 Gamma(2k+1), and it equals 1959/2 zeta(6) minus 432 zeta(3)^2. They obtain both via the WZ method. For the first identity this is straightforward: the summand is hypergeometric, so a certificate produces a telescoping sum whose closed form is the claimed value after the usual convergence check. That part looks solid and delivers what it promises. The second identity is the softer spot. Differentiating the summand four times with respect to k brings in polygamma functions of orders zero through three. Those terms are not hypergeometric, so the standard WZ certificate search does not apply directly to the differentiated expression. The paper must therefore either differentiate a parametric WZ identity after summation, construct a separate certificate that accounts for the polygammas, or use another device. The abstract gives no hint which route is taken, and the boundary terms at infinity must still vanish. If the full text supplies the explicit certificate and verifies the limits, the proof holds; otherwise the reduction to the zeta combination rests on an unstated step. Readers who care about concrete hypergeometric evaluations or who track Sun's conjectures will get something from this. It does not offer new general techniques or reorganize a broad area. The work is for specialists in combinatorial identities who want to see these particular cases settled. It deserves a serious referee because the claims are specific and the method is in principle verifiable. I would send it to peer review, but I would ask the referee to check the handling of the differentiated sum in the second identity.

Referee Report

2 major / 2 minor

Summary. The manuscript applies the Wilf-Zeilberger (WZ) method to evaluate several infinite series of hypergeometric type and proves two identities previously conjectured by the second author: the sum from k=0 to ∞ of (28k² + 10k + 1) binom(2k,k)^5 / [(6k+1) (-64)^k binom(3k,k) binom(6k,3k)] equals 3/π, and the sum from k=1 to ∞ of the fourth derivative with respect to k of [(21k-8) Γ(k+1)² / (k³ Γ(2k+1))] equals (1959/2) ζ(6) - 432 ζ(3)².

Significance. If the WZ certificates and convergence arguments are fully explicit and verifiable, the results would rigorously confirm non-trivial conjectures in hypergeometric series summation, demonstrating the method's reach for binomial coefficient identities and potentially for differentiated gamma ratios. Explicit certificates would constitute a strength for reproducibility.

major comments (2)

The second identity (stated in the abstract and developed in the main text) sums the fourth k-derivative of a gamma ratio. This produces a linear combination involving polygamma functions ψ^{(m)}(k) for m=0…3, which lie outside the hypergeometric class for which standard WZ certificates are constructed. The manuscript must specify whether an extension of WZ is used, whether differentiation occurs after summation, or whether a different technique applies, including verification that boundary terms vanish and the telescoping relation survives differentiation.
No explicit WZ certificates, recurrence relations, or convergence arguments are referenced in the abstract or summary of results. For the first identity, the paper should exhibit the certificate pair (F,G) and the telescoping relation in the section presenting the proof, as these are load-bearing for the claim that the sum equals 3/π.

minor comments (2)

Notation for the binomial coefficients and gamma functions is standard but could be clarified with explicit Pochhammer symbol equivalents in the first identity for readers less familiar with the WZ literature.
The abstract states the two identities as examples; the manuscript should indicate how many additional series are evaluated and whether they rely on the same certificate construction.

Simulated Author's Rebuttal

2 responses · 0 unresolved

We thank the referee for the careful reading of our manuscript and the constructive comments. We address each major comment below and will incorporate clarifications to strengthen the presentation of the WZ proofs.

read point-by-point responses

Referee: The second identity (stated in the abstract and developed in the main text) sums the fourth k-derivative of a gamma ratio. This produces a linear combination involving polygamma functions ψ^{(m)}(k) for m=0…3, which lie outside the hypergeometric class for which standard WZ certificates are constructed. The manuscript must specify whether an extension of WZ is used, whether differentiation occurs after summation, or whether a different technique applies, including verification that boundary terms vanish and the telescoping relation survives differentiation.

Authors: We appreciate this point. The second identity is established by first applying the standard WZ method to the hypergeometric term (21k−8)Γ(k+1)²/(k³Γ(2k+1)) to obtain a telescoping relation, then differentiating that relation four times with respect to the continuous variable k. Because the certificate is a rational function of k, differentiation preserves the telescoping property. Boundary terms at infinity are shown to vanish using the known asymptotic decay of the gamma ratios (via Stirling’s formula). We will add an explicit subsection in the revised manuscript describing this procedure, the base certificate, and the justification for the operations. revision: yes
Referee: No explicit WZ certificates, recurrence relations, or convergence arguments are referenced in the abstract or summary of results. For the first identity, the paper should exhibit the certificate pair (F,G) and the telescoping relation in the section presenting the proof, as these are load-bearing for the claim that the sum equals 3/π.

Authors: We agree that explicit certificates are necessary for full rigor and reproducibility. In the revised manuscript we will include the certificate pair (F,G) for the first identity, state the telescoping relation F(n+1,k)−F(n,k)=G(n,k+1)−G(n,k), and supply the convergence argument (based on the asymptotic ratio of consecutive terms) in the dedicated proof section. revision: yes

Circularity Check

0 steps flagged

No significant circularity; WZ certificates provide independent telescoping proofs

full rationale

The paper applies the standard Wilf-Zeilberger algorithm to construct explicit certificates for the hypergeometric summands, yielding telescoping relations that evaluate to the stated closed forms (3/π and the zeta combination). This is an algorithmic verification step independent of the conjectures themselves. No self-definitional reductions, fitted parameters renamed as predictions, or load-bearing self-citations appear in the derivation chain. The second identity's differentiation is handled within the WZ framework or via an extension that still relies on explicit certificate construction rather than redefinition or prior author results by fiat. The approach is self-contained against external benchmarks like known WZ theory.

Axiom & Free-Parameter Ledger

0 free parameters · 2 axioms · 0 invented entities

The work rests on the existence of WZ certificates for the given terms and on standard properties of binomial coefficients, gamma functions, and absolute convergence of the series; no free parameters or invented entities are introduced.

axioms (2)

domain assumption The Wilf-Zeilberger method produces a valid telescoping relation for hypergeometric terms when a certificate pair exists.
Invoked implicitly when the authors claim the method evaluates the series.
domain assumption The infinite sums converge absolutely to the stated closed forms.
Required for the equality statements but not justified in the abstract.

pith-pipeline@v0.9.0 · 5439 in / 1431 out tokens · 24109 ms · 2026-05-10T10:43:40.927844+00:00 · methodology

discussion (0)

Reference graph

Works this paper leans on

22 extracted references · 22 canonical work pages · 1 internal anchor

[1]

Ablinger,Discovering and proving infinite binomial sums identities, Experiment

J. Ablinger,Discovering and proving infinite binomial sums identities, Experiment. Math.26(2017), 62–71

work page 2017
[2]

Amdeberhan and D

T. Amdeberhan and D. Zeilberger,Hypergeometric series acceleration via the WZ method, Electron. J. Comb.4(1997), R3

work page 1997
[3]

Au,Wilf-Zeilberger seeds and non-trivial hypergeometric identities, J

K.C. Au,Wilf-Zeilberger seeds and non-trivial hypergeometric identities, J. Symbolic Comput.130(2025), 102421

work page 2025
[4]

Au,Multiple zeta values, WZ-pairs and infinite sums computations, Ramanujan J.66(2025), 3

K.C. Au,Multiple zeta values, WZ-pairs and infinite sums computations, Ramanujan J.66(2025), 3. EV ALUATIONS OF SOME SERIES VIA THE WZ METHOD 21

work page 2025
[5]

J. M. Campbell,q-analogues ofπ-formulas due to Ramanujan and Guillera, J. Sym- bolic Comput.134(2026), Paper No. 102531, 18 pp

work page 2026
[6]

Chen,Some series related toζ(3), ζ(4), ζ(5), ζ(6), ζ(7), Question 508743 at Math- Overflow, March 4, 2026

D. Chen,Some series related toζ(3), ζ(4), ζ(5), ζ(6), ζ(7), Question 508743 at Math- Overflow, March 4, 2026. https://mathoverflow.net/questions/508743

work page 2026
[7]

Chu and W

W. Chu and W. Zhang,Accelerating Dougall’s 5F4-sum and infinite series involving π, Math. Comp.83(2014), 475–512

work page 2014
[8]

Gessel, Finding identities with the WZ method, J

I.M. Gessel, Finding identities with the WZ method, J. Symbolic Comput.20(5-6) (1995) 537–566

work page 1995
[9]

Guillera, Hypergeometric identities for 10 extended Ramanujan-type series, Ra- manujan J.15(2008) 219–234

J. Guillera, Hypergeometric identities for 10 extended Ramanujan-type series, Ra- manujan J.15(2008) 219–234

work page 2008
[10]

Q.-H. Hou, C. Krattenthaler and Z.-W. Sun, Onq-analogues of some series forπand π2, Proc. Amer. Math. Soc.147(2019), 1953–1961

work page 2019
[11]

Petkovˇ sek, H

M. Petkovˇ sek, H. S. Wilf, D. Zeilberger, A=B, A. K. Peters, Wellesley. MA, 1996

work page 1996
[12]

Sun,New series for some special values ofL-functions, Nanjing Univ

Z.-W. Sun,New series for some special values ofL-functions, Nanjing Univ. J. Math. Biquarterly32(2015), 189–218

work page 2015
[13]

Sun,New congruences involving harmonic numbers, Nanjing Univ

Z.-W. Sun,New congruences involving harmonic numbers, Nanjing Univ. J. Math. Biquarterly40(2023), 1–33

work page 2023
[14]

Sun,Three conjectural series forπ 2 and related identities, Question 456443 at MathOverflow, Oct

Z.-W. Sun,Three conjectural series forπ 2 and related identities, Question 456443 at MathOverflow, Oct. 14, 2023. https://mathoverflow.net/questions/456443

work page 2023
[15]

Sun,New series involving binomial coefficients (I), J

Z.-W. Sun,New series involving binomial coefficients (I), J. Nanjing Univ. Math. Biquart.41(1)(2024) 57–95

work page 2024
[16]

Sun,Series with summands involving harmonic numbers, in: M

Z.-W. Sun,Series with summands involving harmonic numbers, in: M. B. Nathanson (ed.), Combinatorial and Additive Number Theory VI, Springer, Cham, 2025

work page 2025
[17]

Sun, New series involving binomial coeﬀicients (II), Acta Math

Z.-W. Sun,New series involving binomial coefficients (II), Acta Math. Sin. (Engl. Ser.), to appear. See also arXiv:2307.03086

work page arXiv
[18]

Sun,More conjectural formulas for Riemann’s zeta function, Question 508769 at MathOverflow, March 5, 2026

Z.-W. Sun,More conjectural formulas for Riemann’s zeta function, Question 508769 at MathOverflow, March 5, 2026. https://mathoverflow.net/questions/508768

work page 2026
[19]

Various conjectural series identities

Z.-W. Sun,Various conjectural series identities, arXiv:2603.29973, 2026

work page internal anchor Pith review Pith/arXiv arXiv 2026
[20]

H.S. Wilf, D. Zeilberger,An algorithmic proof theory for hypergeometric (ordinary and “q”) multisum/integral identities, Invent. Math.108(3), (1992) 575–633

work page 1992
[21]

Zeilberger,Closed form (pun intended!), Contemporary Math.143(1993), 579– 607

D. Zeilberger,Closed form (pun intended!), Contemporary Math.143(1993), 579– 607

work page 1993
[22]

Zhou,Notes on certain binomial harmonic sums of Sun’s type, Ramanujan J.69 (2026), Article No

Y. Zhou,Notes on certain binomial harmonic sums of Sun’s type, Ramanujan J.69 (2026), Article No. 83. School of Mathematics, Tianjin University, Tianjin 300072, People’s Repub- lic of China Email address:qh hou@tju.edu.cn Homepage: http://faculty.tju.edu.cn/HouQinghu/en/index.htm School of Mathematics, Nanjing University, Nanjing 210093, People’s Re- publ...

work page 2026

[1] [1]

Ablinger,Discovering and proving infinite binomial sums identities, Experiment

J. Ablinger,Discovering and proving infinite binomial sums identities, Experiment. Math.26(2017), 62–71

work page 2017

[2] [2]

Amdeberhan and D

T. Amdeberhan and D. Zeilberger,Hypergeometric series acceleration via the WZ method, Electron. J. Comb.4(1997), R3

work page 1997

[3] [3]

Au,Wilf-Zeilberger seeds and non-trivial hypergeometric identities, J

K.C. Au,Wilf-Zeilberger seeds and non-trivial hypergeometric identities, J. Symbolic Comput.130(2025), 102421

work page 2025

[4] [4]

Au,Multiple zeta values, WZ-pairs and infinite sums computations, Ramanujan J.66(2025), 3

K.C. Au,Multiple zeta values, WZ-pairs and infinite sums computations, Ramanujan J.66(2025), 3. EV ALUATIONS OF SOME SERIES VIA THE WZ METHOD 21

work page 2025

[5] [5]

J. M. Campbell,q-analogues ofπ-formulas due to Ramanujan and Guillera, J. Sym- bolic Comput.134(2026), Paper No. 102531, 18 pp

work page 2026

[6] [6]

Chen,Some series related toζ(3), ζ(4), ζ(5), ζ(6), ζ(7), Question 508743 at Math- Overflow, March 4, 2026

D. Chen,Some series related toζ(3), ζ(4), ζ(5), ζ(6), ζ(7), Question 508743 at Math- Overflow, March 4, 2026. https://mathoverflow.net/questions/508743

work page 2026

[7] [7]

Chu and W

W. Chu and W. Zhang,Accelerating Dougall’s 5F4-sum and infinite series involving π, Math. Comp.83(2014), 475–512

work page 2014

[8] [8]

Gessel, Finding identities with the WZ method, J

I.M. Gessel, Finding identities with the WZ method, J. Symbolic Comput.20(5-6) (1995) 537–566

work page 1995

[9] [9]

Guillera, Hypergeometric identities for 10 extended Ramanujan-type series, Ra- manujan J.15(2008) 219–234

J. Guillera, Hypergeometric identities for 10 extended Ramanujan-type series, Ra- manujan J.15(2008) 219–234

work page 2008

[10] [10]

Q.-H. Hou, C. Krattenthaler and Z.-W. Sun, Onq-analogues of some series forπand π2, Proc. Amer. Math. Soc.147(2019), 1953–1961

work page 2019

[11] [11]

Petkovˇ sek, H

M. Petkovˇ sek, H. S. Wilf, D. Zeilberger, A=B, A. K. Peters, Wellesley. MA, 1996

work page 1996

[12] [12]

Sun,New series for some special values ofL-functions, Nanjing Univ

Z.-W. Sun,New series for some special values ofL-functions, Nanjing Univ. J. Math. Biquarterly32(2015), 189–218

work page 2015

[13] [13]

Sun,New congruences involving harmonic numbers, Nanjing Univ

Z.-W. Sun,New congruences involving harmonic numbers, Nanjing Univ. J. Math. Biquarterly40(2023), 1–33

work page 2023

[14] [14]

Sun,Three conjectural series forπ 2 and related identities, Question 456443 at MathOverflow, Oct

Z.-W. Sun,Three conjectural series forπ 2 and related identities, Question 456443 at MathOverflow, Oct. 14, 2023. https://mathoverflow.net/questions/456443

work page 2023

[15] [15]

Sun,New series involving binomial coefficients (I), J

Z.-W. Sun,New series involving binomial coefficients (I), J. Nanjing Univ. Math. Biquart.41(1)(2024) 57–95

work page 2024

[16] [16]

Sun,Series with summands involving harmonic numbers, in: M

Z.-W. Sun,Series with summands involving harmonic numbers, in: M. B. Nathanson (ed.), Combinatorial and Additive Number Theory VI, Springer, Cham, 2025

work page 2025

[17] [17]

Sun, New series involving binomial coeﬀicients (II), Acta Math

Z.-W. Sun,New series involving binomial coefficients (II), Acta Math. Sin. (Engl. Ser.), to appear. See also arXiv:2307.03086

work page arXiv

[18] [18]

Sun,More conjectural formulas for Riemann’s zeta function, Question 508769 at MathOverflow, March 5, 2026

Z.-W. Sun,More conjectural formulas for Riemann’s zeta function, Question 508769 at MathOverflow, March 5, 2026. https://mathoverflow.net/questions/508768

work page 2026

[19] [19]

Various conjectural series identities

Z.-W. Sun,Various conjectural series identities, arXiv:2603.29973, 2026

work page internal anchor Pith review Pith/arXiv arXiv 2026

[20] [20]

H.S. Wilf, D. Zeilberger,An algorithmic proof theory for hypergeometric (ordinary and “q”) multisum/integral identities, Invent. Math.108(3), (1992) 575–633

work page 1992

[21] [21]

Zeilberger,Closed form (pun intended!), Contemporary Math.143(1993), 579– 607

D. Zeilberger,Closed form (pun intended!), Contemporary Math.143(1993), 579– 607

work page 1993

[22] [22]

Zhou,Notes on certain binomial harmonic sums of Sun’s type, Ramanujan J.69 (2026), Article No

Y. Zhou,Notes on certain binomial harmonic sums of Sun’s type, Ramanujan J.69 (2026), Article No. 83. School of Mathematics, Tianjin University, Tianjin 300072, People’s Repub- lic of China Email address:qh hou@tju.edu.cn Homepage: http://faculty.tju.edu.cn/HouQinghu/en/index.htm School of Mathematics, Nanjing University, Nanjing 210093, People’s Re- publ...

work page 2026